RU2281387C2 - Method of action application to oil pool fluid during oil production - Google Patents

Abstract

FIELD: oil production industry, particularly enhanced recovery methods for obtaining hydrocarbons.

SUBSTANCE: method involves lowering resonance-wave device in well; creating oscillations with predetermined frequency in oil fluid to be treated within oil production zone. The resonance-wave device is submersed in one of wells drilled in area to be treated. Movable resonance modules, wave conductors and loops are arranged on resonance-wave device surface. Oscillations are directly created in oil fluid to be treated by forming carrier electromagnetic waves within frequency range of from 3-10^-5 to 3-10¹⁴ Hz or ultrasound waves within frequency range of from 1.5-10⁴ to 10⁹ Hz or acoustic waves within frequency range of from 17 Hz to 20 kHz. The waves are modulated by information signals, which are resonant with hydrocarbons of oil fluid to be treated and are converted into standing waves.

EFFECT: improved oil output due to increased oil recovery ratio and oil production rate, increased oil quality and flow (kinetic) properties, increased volume of fluid to be extracted along with decreased water content in the fluid.

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Description

The invention relates to the oil industry and can be used to increase the oil recovery coefficient (CIN), its flow rate, improve the quality and rheological (kinetic) properties, increase the volume of pumped fluid, while reducing its water content.

A known method of intensifying oil production, including the descent into the well of tubing, a sound generator, for example, a pump on a tubing of an acoustic device, in the form of a resonator-sound generator, excitation of sound vibrations by a pump and transformation of sound vibrations by an acoustic resonator-generator (SU No. 794200, publ. 07.01.1981).

The disadvantage of this method is that when transforming an acoustic resonator-generator of sound sound, there is no high-frequency region of the ultrasonic range with which oil can be degassed, followed by a decrease in viscosity and an increase in well production.

A known method of influencing the fluid of oil fields during oil production, which consists in creating an oscillatory process of a given frequency in the processed oil fluid in the zone of oil production (RU No. 2133332, Е 21 В 43/00, 43/25, publ. 07.20.1999).

This method of intensifying oil production includes the descent into the well of tubing, a sound generator, for example a pump on tubing, an acoustic device in the form of a resonator-sound generator, pump excitation of sound vibrations and transformation of sound vibrations by an acoustic resonator-generator, when this acoustic resonator-sound generator is placed on the bottom of the well, and the transformation of sound vibrations by the transformation of low-frequency waves in the region s high ultrasonic frequency range, which the degassed oil, followed by reduction of its viscosity, increase the well production rate.

The disadvantage of this method is that it did not use the entire arsenal of possible radiations for the vibrational treatment of the oil fluid and combinations of these radiations. As a result, there is limited application of the known method. Given the instability of the composition of the oil fluid, depending on the location of the field, an effective method for one type of oil production may not be as effective for another field.

The present invention is directed to solving the technical problem of providing resonant excitation and decomposition of hydrocarbon fluids into lighter hydrocarbons and resonant energization of fluid water with a change in its physical properties.

The technical result achieved in this case is to increase the efficiency of oil production by increasing the oil recovery coefficient, its production rate, improving the quality and rheological (kinetic) properties, increasing the volume of pumped fluid while reducing the water content in it.

The specified technical result is achieved by the fact that in the method of influencing the fluid of oil fields during oil production, which consists in creating an oscillatory process of a given frequency in the oil being processed in the oil production zone, the oscillating process is carried out directly in the oil being processed in the form of radiation formed into standing waves carrier electromagnetic waves in the frequency range 3 × 10 ^-5 to 3 × 10 ¹⁴ Hz and / or ultrasonic waves in the frequency range from 1.5 × 10 ⁴ to 10 ⁹ Hz, and / or ac oral waves in the frequency range from 17 Hz to 20 kHz, modulated by information signals, resonant hydrocarbons of the processed oil fluid.

These features are significant and interconnected with the formation of a stable set of essential features sufficient to obtain the desired technical result.

When implementing the specified set of features, the technical result is achieved due to:

- Resonant excitation and decomposition of fluid hydrocarbons into lighter hydrocarbons and resonant energy of fluid water with a change in its physical properties.

- Decrease in fluid viscosity and its separation into light hydrocarbons and energized water.

- Redistribution of fluid hydrocarbons in the upper parts of the fields to oil wells, and energized fluid in the lower parts of the fields.

- Displacement of hydrocarbons by energized fluid from the lower sections of the fields to the upper to oil wells.

- Improving the drainage function of cracks, microcracks, capillaries and pores of the fields when their lumen is released from:

a) heavy hydrocarbons deposited and adhering to their wall, asphaltene-paraffin-resinous deposits, etc. upon resonant excitation and their splitting under the influence of resonance-wave technology into light moving fractions (complexes);

b) clays, colloid-dispersed formations, rock microparticles, etc., when dissolved and / or washed out by energized fluid, redistributed to the lower parts of the deposits;

c) water adsorbed and firmly bound to the surface of the mineral particles of their wall by the forces of ionic, molecular, capillary and feather attraction, when it is energized and the physical properties change under the influence of resonance-wave technology.

- Increases in pressure in reservoirs due to:

a) increasing the temperature of the fluid and lowering its viscosity when exposed to resonant wave technology;

b) an increase in the concentration gradient of light resonantly excited hydrocarbon fluids, characterized by a higher thermal rate from heavy hydrocarbons, at a given temperature of the formations;

c) changes in the physical properties of energized fluid water, characterized by a lower boiling point, increased response (mobility) to mechanical, temperature, acoustic, ultrasonic, electromagnetic, geomagnetic, gravitational and other influences; increased vaporization, etc.

Increasing the permeability of cracks, microcracks, capillaries and pores of deposits for hydrocarbons redistributed through them from the lower to the upper sections of the deposits to oil wells, due to:

a) the formation in their marginal, parietal zones, multimolecular monolayers of energized, mobile fluid water, which prevents the adhesion (deposition and adherence) of hydrocarbons to the wall, and ensures their unhindered redistribution to the upper sections of the deposits;

b) imparting hydrophobic properties to light hydrocarbon fluids by resonant wave action, preventing their mixing with wall monolayers of energized fluid fluid, separating hydrocarbons from the walls of cracks, microcracks, capillaries and pores.

In accordance with the present invention, a method of exposing a fluid to oil fields during oil production involves exposing the fluid to radiation. Carrying electromagnetic waves are used as radiation in the frequency range 3 × 10 ^-5 to 3 × 10 ¹⁴ Hz and / or ultrasonic waves in the frequency range from 1.5 × 10 ⁴ to 10 ⁹ Hz, and / or acoustic waves in the frequency range from 17 Hz to 20 kHz. Carrying electromagnetic and / or ultrasonic waves and / or acoustic waves are modulated by information signals, resonant hydrocarbon fluids, formed into standing waves and sent to the processed fluid.

The physical essence of the method for intensifying oil production consists in exposure to radiation in the form of an oscillatory process on the evolution of gas from a liquid.

Oscillations emitted into a liquid medium create a wave field that changes the characteristics of the medium and the processes occurring in it: the speed, attenuation coefficient, etc. change. In addition, processes such as cavitation, degassing, acoustic flows, etc., occur in the medium.

The value of the wave field intensity necessary for influencing the medium substantially depends on its initial thermodynamic state. In order to transfer the system from a state of stable thermodynamic equilibrium to a new stationary state, huge energy of external influence is required. If the system is in a state close to thermodynamic instability (metastable state), then an external effect of even low intensity can translate it into a qualitatively new state.

The system becomes unstable when the value of a characteristic parameter is close to critical. Therefore, it is energetically most beneficial to effect a system in a metastable state.

In the work of Kuznetsov I.L., Efimova S.A. "The use of ultrasound in the oil industry", M, Nedra, 1983. - p. 26-27, p. 75-79 it is shown that in an acoustic field with an intensity of 8-10 kW / m ² at a frequency of 5-20 kHz is experimentally observed a change in the shear viscosity of oils (a decrease in the viscosity of a liquid in an acoustic field is explained by its partial heating due to absorption of elastic energy and breaking of bonds in individual macromolecules during cavitation).

Typically, the viscosity of a liquid after such an acoustic effect initially decreases by 20-30%, and subsequently either recovers (in the pre-cavitation and weakly cavitation mode), or does not recover (in the developed cavitation mode).

Such parameters, i.e. an acoustic field with an intensity of 8-10 kW / m ² with a frequency of 18-25 kHz can be obtained with a special acoustic resonator-sound generator (for example, a Helmholtz resonator) to intensify oil production. In addition, such a generator does not need electric energy or the energy of a liquid (gas) stream. It works on the energy of elastic vibrations of fluid filtration noise and elastic vibrations of a submersible installation (a deep electric centrifugal pump, lowered into the borehole on tubing), the frequency of which extends to the bottom.

Thus, according to the results of the research and experiments, a method for influencing the fluid of oil fields during oil production was formulated in the form of an algorithm, which consists in creating an oscillatory process of a given frequency in the processed oil fluid in the oil production zone, while the oscillatory process is carried out directly in the processed oil fluid in the form of radiation-formed carrier by electromagnetic waves in the standing wave in the frequency range of 3 × 10 ^-5 to 3 × 10 ¹⁴ Hz and / or st of an ultrasonic wave in the frequency range from 1,5 × 10 ⁴ to 10 ⁹ Hz, and / or acoustic waves in the frequency range from 17 Hz to 20 kHz modulated information signals resonance hydrocarbons treated petroleum fluid.

Example (based on the use of resonant-wave technology at the N-th oil field):

Two sections of the N-th oil field, which are located at a distance of 7 km from each other, were simultaneously exposed to resonance-wave action. There were 4 wells in each section. The distance between the wells varied from 200 to 800 m. All wells were perforated at different horizons. On the perimeter from both demonstration sites within a radius of 3 km, control zones with working wells located on them were allocated. In total, there were 17 working wells around the first section, and 35 working wells around the second section (a total of 52 control wells). A prerequisite for the demonstration was the absence of any changes to the operating conditions of oil production equipment and its operation mode.

In these wells, the oil fluid was irradiated with electromagnetic waves in the frequency range 3 × 10 ^-5 to 3 × 10 ¹⁴ Hz and / or ultrasonic waves in the frequency range from 1.5 × 10 ⁴ to 10 ⁹ Hz, and / or acoustic waves in the frequency range from 17 Hz to 20 kHz.

The resonant wave action on the fluid located in the oil-bearing strata of both demonstration sections of the field was carried out by the formation of directed standing waves. To do this, a resonance-wave device (generator) was immersed in one of the wells of each demonstration site on a geophysical cable to a depth of 1200 to 1800 m for a period of 30 to 40 hours. At the same time, an antenna field was placed on the surface of both sections, including mobile resonant modules, waveguides, and circuits for generating and controlling resonant standing waves (the width and depth of the resonant wave capture of the selected areas of the field).

Management effectiveness was evaluated on the basis of the following conditions:

- providing the possibility of obtaining a long, stable and unidirectional shift of the estimated parameters at all 8 demonstration wells in the fluid pumped out from the wells, improving the quality and rheological (kinetic) properties of the recoverable oil - reducing specific gravity, viscosity, excise resin content, coking ability, oil boiling point and an increase in its content of light petroleum products;

- the absence of similar unidirectional changes in the fluid extracted from 52 control wells located around the perimeter from the demonstration sites;

- providing, at a predetermined time, the expansion of the resonance-wave capture zone of the field, involving fluid in the control zones of the field involved in the resonance process, in order to obtain a unidirectional shift of the studied parameters in the control wells.

The results of the demonstration.

1. The rate of oil. As a result of the resonance-wave action on the fluid, the oil production rate at demonstration wells increased from 100% to 600-700%, and in individual wells this indicator exceeded 1000%.

2. The percentage of water. The percentage of water in the pumped fluid decreased by an average of 65-70%, and in some wells the water completely disappeared.

3. The specific gravity. After the beginning of the resonance-wave action, a steady tendency is observed to a decrease in the specific gravity of the produced oil. Two months after the onset of exposure, the difference was 0.036 units.

4. The viscosity of oil. Under the influence of technology, the viscosity of the produced oil decreased by more than 2 times (33.1 cst - initial value, 15.0 cst obtained value).

5. The content of excise resins. A steady tendency towards a decrease in the content of excise resins in the produced oil was noted; the difference between the initial value and the value obtained by resonant-wave exposure amounted to 33.3%.

6. Cokeability. There is a steady trend towards a decrease in coking properties. Compared with the initial level, coking ability on average decreased by 42.3%.

7. The temperature of the onset of boiling oil. A steady tendency towards a decrease in the temperature of the onset of oil boiling is noted. The maximum difference between the initial value and the value at the end of the second month of the influence of the resonance-wave technology on the fluid was 52 ° C.

8. The output of light fractions during the distillation of oil. A steady tendency has been registered for an increase in the yield of light oil products during the distillation of oil at all temperature conditions. The beginning of the yield of light fractions at a temperature of 100 ° C, which previously could not be obtained, was noted. The increase in the yield of light fractions was:

- at 100 ° С -7.3%

- at 150 ° С -14.5%

- at 200 ° С -14%

- at 300 ° C -13%.

The control over the propagation of the zone of resonance-wave action on the fluid of the field was carried out as follows.

During the first two months, the fluid was exposed to resonance wave only in the demonstration areas of the oil field. During this period of exposure in the control zone of the field (52 wells), no significant changes in the studied parameters were detected.

Starting from the 3rd month, the program of resonance-wave action was expanded and aimed at the fluid located in the control zone of the field.

3-4 days after the expansion of the zone of resonance-wave action on the field, a steady tendency was observed for the directional growth of the studied parameters of oil in control wells, similar to the changes that took place at the demonstration sites.

Analysis and comparison of the obtained results with the field indicators presented in the reports on the N-field over the past 8 years indicates that such a significant and lasting (over 1 year) increase in oil production, while reducing the water content in the pumped fluid, occurred under the influence of resonance-wave technology by increasing the oil recovery factor: when the fluid is divided into hydrocarbons and water; redistribution of water into the lower sections of the field and the displacement of hydrocarbons from them into the upper sections of the field to oil wells.

This is also evidenced by the fact that an increase in the oil production rate with a decrease in the water content in the fluid pumped out of the field occurs precisely in those parts of the field that are subjected to resonance-wave action, while in the neighboring control zones of this field there are any significant changes in the studied parameters not happening.

The improvement in the quality of the recoverable oil and its rheological properties, not observed at the N-oil field for the entire previous period of its operation (over 20 years), is caused by resonance-wave splitting (cracking) of fluid hydrocarbons with the directed influence of resonance-wave technology on it.

An important factor is the fact that the effect of the resonance-wave action manifests itself in a short time after its onset and persists throughout the entire period of exposure.

The resonance-wave effect is characterized by a high degree of controllability and directionality and does not require any changes to the existing processes in the oil industry and the equipment used, as well as additional energy costs.

Using the technology of resonant wave action on a fluid allows:

1. To reanimate off-balance deposits and significantly extend the life of deposits characterized by low flow rates, waterflooding, heavy oils, etc. by increasing the oil recovery coefficient, its quality and rheological properties, while reducing the water content in the pumped fluid.

2. To reduce costs and terms of field development by reducing the number of wells drilled with increasing distance between them.

3. To reduce the amount of time-consuming work and the costs of the operation and overhaul of wells.

4. Significantly reduce the costs associated with transportation through the pipeline and refining at refineries (refineries) of high-quality, light oil extracted from oil fields using resonance wave technology (RWT).

5. Subjecting preliminary resonant-wave action to the oil contained in the pipes and storage tanks of oil refineries (refineries), significantly increase the content of light oil products and their selection during subsequent processing in distillation units of the refinery.

Using the present method allows to obtain:

- Increase in oil recovery ratio;

- Increase in oil production;

- Improving the quality and rheological (kinetic) properties of oil extracted from fields: reducing its specific gravity and viscosity; reduction of excise resin and paraffin content; decrease in coking ability and temperature of the beginning of oil boiling; increase in the content of light oil products (light hydrocarbons); increasing the mobility of oil and giving it hydrophobic properties.

- An increase in the volume of fluid pumped out from the fields with a decrease in its viscosity.

- A decrease in the water content in the fluid pumped out of the fields upon a change in its physical properties: a significant increase in wetting, washing, and dissolving properties; lower boiling point; increased evaporation and vaporization; increased permeability of microcracks, capillaries, pores, etc.

The present invention is industrially applicable, as it can be repeatedly used in any wells with various mechanized methods of oil production and implemented using standard submersible equipment that allows the implementation of electromagnetic radiation in the frequency range 3 × 10 ^-5 to 3 × 10 ¹⁴ Hz and / or ultrasonic waves in the frequency range from 1.5 × 10 ⁴ to 10 ⁹ Hz, and / or acoustic waves in the frequency range from 17 Hz to 20 kHz.

Claims (1)

The method of influencing the fluid of oil fields during oil production, which consists in immersing a resonant wave device in the well and creating an oscillatory process of a given frequency in the oil being processed in the oil production zone, characterized in that the resonant wave device is immersed in one of the wells of the treated section and moving resonant modules, waveguides and circuits are placed on its surface, the oscillatory process is carried out directly in the oil being processed electromagnetic waves in the frequency range 3 · 10 ^-5 to 3 · 10 ¹⁴ Hz or ultrasonic waves in the frequency range from 1.5 · 10 ⁴ to 10 ⁹ Hz, or acoustic waves in the frequency range from 17 Hz to 20 kHz, which modulate information signals, resonant hydrocarbons of the processed oil fluid, and form in standing waves.